KR200256136Y1 - Traction drive elevator - Google Patents

Abstract

In a towing drive elevator system having at least one counterweight, a cage and a pair of vertical tracks to support a portion of the load in the cage, the tow drive having a frame separate from the cage is used to drive two sets of drives. Each comprising a pair of small diameter counter rollers and a large tow roller located on opposite surfaces of one of the tracks, wherein the axis of the tow roller is preferably horizontal in a high central passage between the axes of the counter rollers, The counter roller is movable towards the track, the eccentric device coupled with the gas spring pushes the counter roller towards the track, thereby creating a friction force between the roller and the track, the gearbox and the motor including the worm and spur gear coupling Optionally rotate the tow roller to move the car between the landings, and finally the safety bar When the spring fails, the traction is maintained between the wheel and the track, preferably the track constitutes one of the tracks protruding into the two rails of the U-shaped cross section, the counter roller is located in the U-shape, The towing roller is located on the outside of the rail, for which it is made of a relatively large diameter, and the other track is used to guide the counterweight.

Description

Traction Drive Elevator {TRACTION DRIVE ELEVATOR}

The present invention relates to an elevator, such as a freight elevator, and a passenger operating between two or more floors or boarding floors.

Currently, there are two types of elevators: traction elevators and hydraulic elevators. In towed elevators, elevator hoists are usually suspended by steel ropes within the elevator aisle. The rope extending up to the top of the elevator shaft is directed towards the upper drive pulley and extends down through the guide pulley to the counterweight. The motor is connected to the drive pulley either directly (so-called "gearless elevator") or through intermediate gear (so-called "geared elevtor") so that the operation of the motor lowers or raises the lift between floors. To do that.

In a hydraulic elevator, the load on the hoist is carried by one or more hydraulic jacks. To raise the cage, the motor pumps fluid from the reservoir to the jack via a control valve. To lower the hoist, the valve is opened to circulate the jack, and the load of the hoist compartment causes the fluid to flow out of the jack and return to the reservoir to lower the hoist.

Towing elevators are designed to operate at a wide range of speeds depending on the intended application and can be provided in all buildings from the second floor to the higher floor. The major drawbacks of towing elevators are the fact that they require a top floor to accommodate motor / drive systems and pulleys, and at a relatively high cost. Hydraulic elevators are less expensive but have limited floors that can be provided, and cannot be as fast as a towed elevator.

My prior art US Pat. No. 5,572,530 discloses an elevator system with a lift car that moves up and down using a traction drive instead of a hydraulic cylinder or pulley and an upper motor. A pair of rollers mounted on the rotating plate are positioned on both sides of the rail and pressed against the rail to generate friction. The motor on the elevator cage drives at least one roller for moving the elevator cage up and down. The elevator has the advantages of a towed elevator in terms of height and high speed to provide it to a higher floor, but no top layer is required to support the drive system and the motor as in conventional towed elevators.

SUMMARY OF THE INVENTION An object of the present invention is a traction drive elevator system having at least one counterweight, a cage and a pair of vertical tracks for supporting a portion of the load of a cage, wherein the traction drive has a frame separate from the cage. Two sets of drives, each comprising a pair of small diameter counter rollers and a large tow roller located on opposite sides of one of the tracks, the axis of the tow roller being horizontal to the high central passage between the axes of the counter rollers Preferably, the counter roller is movable towards the track, and the eccentric device associated with the gas spring pushes the counter roller towards the track, thereby generating friction between the roller and the track, including the worm and spur gear engagement. The gearbox and the motor selectively rotate the towing roller to move the cage between the landing floors. Finally, the safety bar maintains traction between the wheel and the track if the gas spring fails, preferably the track constitutes one of the tracks protruding into the two rails with a U-shaped cross section, and the counter roller Located in a U-shape, the traction roller is located on the outside of the rail, for this purpose is made of a relatively large diameter and the other track is used to guide the counterweight.

1 is a side view of an elevator system in accordance with the present invention, near the side wall of the elevator shaft, omitted for clarity;

2 and 3 are respectively a front view and a plan view of the elevator system without the elevator shaft,

4 is a side view taken along arrow 4-4 in FIG. 3;

5 is a front view of the motor and the gearbox, and

6 and 7 are front and top views of an eccentric bias system used in the system.

The traction drive elevator system mainly consists of a pair of vertical tracks, hoists and counterweights to support some of the load on the hoists. The traction drive, preferably comprising a frame separate from the hoist, comprises two sets of drives, each comprising a pair of small diameter counter rollers and a large traction roller located on opposite sides of one of the tracks. The axis of the traction roller is horizontally parallel to the axis of the counter roller. The towing rollers are maintained vertically at regular intervals between the counter rollers, preferably perpendicular to the midpoint of the counter rollers, and the counter rollers are movable in the direction toward the track. The eccentric device installed with the gas spring pushes the counter roller towards the track, whereby friction occurs between the roller and the track. The motor and gearbox, including the worm and spur gear couplings, selectively rotate the traction rollers to move the cage between the landing layers. As a result, the safety bar maintains traction between the wheel and the track in the event of a gas spring failure.

Preferably, the track consists of one of two tracks projecting into the interior of the U-shaped rail. The counter roller is located in a U-shaped container, and the tow roller is made of a large diameter for positioning outside the rail. The other track is used to guide the counterweight.

A more detailed description of the invention follows the detailed description of the preferred embodiment in conjunction with the accompanying drawings.

FIG. 1 shows an elevator system comprising a cage 10 which is movable on an elevator shaft 11 between a plurality of stages 12, each stage having a conventional hatch door 14. The pair of vertical rails 16a shown in FIG. 1 are supported by a pit floor and are mounted on opposite axial walls using rail mounting brackets 18 (omitted for clarity). It is fixed to). The pair of ropes, shown as “20” in FIG. 1, each has one end connected to the hoist 10, and the upper pulleys for the pair of counterweights 24 to maintain the load of the hoist 10. 22). As a result, FIG. 1 shows one of two traction drives 26, each comprising a motor 28 and a drive wheel 30. Traction drive 26 is described in more detail below.

2-4, each of the rails 16a, 16b is in contact with the interior in a U-shaped cross section to define a pair of parallel and inwardly facing tracks 36, 37. As shown in FIG. 4, the U-shaped cross section is formed by connecting two rectangular cross-sections 32, that is, using brackets 34 together. Alternatively, a single U-shaped rail may be used. Preferably the rails 16a, 16b are made by machine or cold extrusion, and conventional safety devices (not shown) may be used.

The traction drive 26 is a self unit comprising a frame 50 formed by various crossover elements 52 and end plates 54. In this way, the traction drive 26 can be manufactured separately from the hoist 10. The motor 28 supported by the frame 50 is connected to the gear box 56. The drive shaft 58 extends in each direction from the gear box 56 via a bearing 60 supported on each end plate 54 and is connected to each end with a traction wheel 30.

Each traction drive 26 includes two pairs of counter rollers 38, 40. Each counter roller 38, 40 is rotatably mounted on a shaft 42 supported by the eccentric device 44 as described below. The gas spring mechanism 46 operating between each pair of counter rollers 38 and 40 causes an eccentricity to push the counter rollers 38 and 40 toward the traction roller 30.

The axes of the counter rollers 38 and 40 are located above and below, respectively, above and below the rotation axis of the towing roller 30. Preferably the axis of the traction roller 30 is a vertical intermediate passage between the two axes of the two counter rollers 38, 40. In the method, when the counter rollers 38, 40 are pushed toward the track 36 (as described below), the roller will press against the track 36 without generating torque about the horizontal axis.

Each pair of track wheels 30 and counter rollers 38, 40 are located on opposite surfaces of the track 36 and of the gas spring 46 that presses the traction wheel 30 toward the corresponding counter rollers 38, 40. The force causes the wheels 30, 38, 40 to withstand the track 36 and cause friction between the traction wheel and the track 36.

Referring to FIG. 4, each drive roller 30 comprises a metal hub 31 whose outer surface is covered by an annular ring 33 made of a plastic material such as polyurethane, which contacts the track 36. It is bonded with the metal surface of the hub 31 to increase the coefficient of friction of the roller 30 surface. If desired, the mated surface of the track 36 may be roughened to increase the friction value.

Two counterweight pulleys 22 are supported at the top of the two rails 16a and 16b, respectively, and each counterweight rope 20 extends downward relative to each counterweight 24 by turning one of the pulleys 22. (See FIGS. 3 and 4). Each counterweight includes a guide 62 (see FIGS. 3 and 4) which is connected to the other track 37 of the U-shaped rails 16a and 16b.

As shown in FIG. 5, this represents a more detailed motor / drive assembly in which the motor 28 is connected with the integral brake 70 and the hand crank 72 manually lifts the cage 10 in an emergency. It is provided for raising and lowering. The output shaft of the motor 28 is coupled to the gearbox shaft 76 mounted on the worm 80. The worm 80 is engaged with the worm wheel 82 and is mounted on the pinion gear 86 and the common shaft 84 for rotation. The pinion gear 86 preferably has a smaller diameter than the worm wheel 84. The pinion gear is in turn engaged with the relatively large diameter spur gear 88 and drives the shaft 58 coupled to the traction wheel 30. The combination of the worm and spur gears is engaged so that the motor output shaft is lowered to the desired speed for driving the traction roller 30 in a very effective and quiet manner.

6-7 show gas spring assembly 46 in more detail. Collar 90 is fixed to a shaft 42 on which counter rollers 38 and 40 are rotatably mounted, and includes a radially extending torque arm 92. The gas spring 94 has opposing ends connected by pins 96 to opposing torque arms 92a and 92b. The gas spring pushes away two torque arms with a predetermined force.

In addition to the gas spring, the safety bar 97 has one end 98 fixedly connected to the torque arm 92a. Opposite end 99 extends through hole 100 formed in torque arm 92b. The opposite end 99 includes a threaded portion 102 and a pair of nuts 104.

During operation, the gas spring 94 pushes the two torque arms 92a and 92b apart, causing the elevator shaft 42 to rotate in the eccentric, thereby driving the wheels 38 and 40 toward the traction wheel 30. Push The nut 104 is adjusted so that there is a slight gap, for example about 5 mm, between the nut 104 and the torque arm 92b. In this way, the gas spring 94 is automatically adjusted for wear during normal operation to maintain a constant force between the wheels 39, 40, 30. If the gas spring fails, the torque arms 92a, 92b move only slightly and engage the torque arm 92b after the initial movement of the nut 104, thus preventing the torque arm from falling further. The gap between the nut 104 and the torque arm 92b is adjusted and if the gas spring 94 fails, the safety bar 97 moves the roller to move the cage 10 until the repair is effective. Maintain sufficient traction between the track and the track.

Because of this fact, in the preferred embodiment, two counterweights are used, the rail and the door are centered in the shaft, and it is possible to use a small shaft. In addition, because the U-shaped rails are very tight and fixed on the bottom of the pit, the wall cannot withstand large forces.

The foregoing represents a preferred embodiment of the present invention. Changes and variations in materials and processes disclosed herein can be understood by those skilled in the art without departing from the scope of the invention disclosed herein. For example, because U-shaped rails are used to provide track surfaces for both traction drive wheels and counterweight guides, rail sections such as hollow rails or T-shaped rails can be used as separate rails for other counterweights. It is possible to use and can be adopted for the traction drive. Also, since the counterweight rope is shown as abutting the hoist, it can instead be connected to the traction drive. Moreover, two, more than two or other alignments of counterweight systems may be employed. And, in order to be able to move toward the track, in the present invention, the counter roller is provided eccentrically, and only one of the counter rollers needs to be movable, and the eccentric device and other means can be provided for the movement. Modifications and variations within the scope of the invention are as defined in the following claims.

Claims (11)

In an elevator system, At least two landing layers; A first track extending in the vertical direction between the landing layers; Elevator car; Counterweight device comprising a rope and pulley for supporting a portion of the load of the hoist; At least one tow roller and a pair of counter rollers, the tow roller and the counter roller being located on opposite sides of the first track, each roller having a horizontal axis, the axis of the tow roller being between the axes of the counter rollers A towing drive positioned at a vertical height in the at least one of the counter rollers, the traction drive being movable in a horizontal direction toward the track; A device for pushing the counter roller towards the track; Drive means for selectively rotating said tow roller for moving said cage between the landing layers; And And means for coupling the traction drive to the hoist. The method of claim 1, And the means for pushing the counter roller toward the track comprises a gas spring. The method of claim 2, At least one movable counter roller is supported by eccentric means, and the gas spring acts on the eccentric means that pushes the counter roller towards the track. The method of claim 3, wherein Said eccentric means comprises at least one torque arm and said gas spring is connected to said torque arm. The method of claim 4, wherein And a safety bar connected to said torque arm to allow for a predetermined amount of movement of said torque arm. The method of claim 5, A second torque arm, the other of said counter rollers being supported by eccentric means to be movable in a horizontal direction towards said track, said gas spring being connected between said torque arms, and said safety bar being said second An elevator system, characterized in that it has an end fixed to the torque arm. The method of claim 1, The traction drive comprises a traction drive frame separated from the hoist compartment, the roller and the drive means being supported by the traction drive frame. The method of claim 1, The traction drive includes a motor, a worm gear coupled to the motor, a worm wheel connected to the worm gear, a pinion gear installed on a common axis having the worm wheel to rotate together, a spur gear connecting the pinion gear, and the And an output shaft coupled to a traction wheel and the spur gear. The method of claim 1, A second track extending parallel to the first track; Means for pushing a second counter roller pair toward the track; And Drive means for selectively rotating the second traction roller for moving the cage between the landing layers, the traction drive comprising a second counter roller pair and a second traction roller, the second traction A roller and a second counter roller pair are located on opposite sides of the second track, and the axis of the tow roller is located at a vertical height between the axes of the second pair of counter rollers, one of the second counter roller pairs being An elevator system, characterized in that it is movable toward the track. The method of claim 9, The counterweight means comprise a pair of pulleys, a pair of counterweights and a pair of ropes respectively supported at the upper ends of the first and second tracks, each rope coupled to the hoisting compartment and being pulled out of the pulley. An elevator system, characterized in that one extends back to one of the parallel weights. The method of claim 9, A first rail and a second rail on opposite sides of the hoisting compartment, one track of the first rail forming the first track and one track of the second rail forming the second track, each The rail has an U-shaped cross section inwardly contacting and defining a pair of parallel tracks, the parallel weight comprising guide means for connecting with one of the other tracks of the first rail and the second rail. .